RU2406542C2 - Method of anesthetic dosage and device for its implementation - Google Patents

Abstract

FIELD: medical technics.

SUBSTANCE: method involves division of carrier gas flow into two flows and directing them along two lines, first of which passes forth to mixing with the second separated flow, which has passed along the second line through evaporator and anesthetic layer and was saturated with anesthetic fumes. The two flows are united and mixed in a mixing chamber before they are supplied to a user. Concentration is sustained due to cyclical shutting the second line and simultaneous admission of separated carrier gas flow through the first line for a definite constant time interval. Then the first line is shut and simultaneously the separated carrier gas flow is let through the second line for another definite constant time interval. Then the separation cycle is repeated for multiple times. Concentration adjustment is performed by changing ratio of time intervals during which the first and second lines are opened and/or shut. An anesthetic dosage device is described.

EFFECT: accuracy of anesthetic dosage.

2 cl, 4 dwg

Description

The invention relates to medical equipment and can be used in anesthesiology departments of medical units and institutions during inhalation anesthesia.

The first vaporizers were developed by the Snow anesthetist in 1847. In particular, he was offered an effective evaporation chamber made in the form of a spiral channel above the surface of the ether. Later, at the beginning of the 20th century, thermometers and switchgears were used, which simultaneously served as manual temperature compensators. Starting from the second half of the 20th century, anesthetic dosing devices appeared using the method of dividing the carrier gas stream into two parts, where the first part of the gas is completely saturated with anesthetic vapor and then diluted with the second part to a predetermined concentration. The change in concentration was carried out by chokes, changes in temperature, pressure, design of the evaporator and other structural elements with elements of control, dosing and blocking. In the last 30 years and to the present, the improvement of the dosing and control process is being implemented at the expense of modern computer technology.

A known method of dispensing anesthetics, including dividing the total carrier gas stream into two continuous flows and directing them along two lines, the first of which goes along the first line to mix with the second stream passing through the second line and passing through the evaporator, saturates it with anesthetic vapor and their combination and mixing in the mixing unit. In this case, the separation of flows and a predetermined concentration is ensured by the use of chokes, and the flow of the stream going to saturation into the evaporation chamber is fed into the vaporizing layer of the anesthetic (See A.Z. Berlin, A.V. Meshcheryakov. Anesthesia and dosing of anesthetics. - M .: Medicine, 1980, p. 18-19). The disadvantage of this method is the impossibility of obtaining a stable volume concentration of anesthetic vapor, due to the fact that, firstly, the resistance coefficients of the throttling devices dividing the flow into the first line and the second line going through the evaporation chamber change when the total gas flow changes as the carrier, and the division coefficient, which leads to unauthorized redistribution of flows, and, secondly, with the fact that the temperature of the surface layer of the anesthetic, from which, in fact, occurs arenes varies during operation, whereby the volume concentration of the anesthetic vapor is changed even in the evaporation chamber. An unpredictable combination of these deviations leads to significant instability in the implementation of this method.

There is also a known method of dispensing anesthetics, adopted as a prototype, comprising dividing the total carrier gas stream into two continuous flows and directing them along two lines, the first of which goes along the first line to mix with the second stream going through the second line and passing through the evaporator, its saturation with anesthetic pairs and their combination and mixing in the mixing chamber. At the same time, the separation of flows and a given concentration is ensured by rotameters, and the flow of the stream going to saturation into the evaporation chamber is fed into it under a layer of anesthetic (See A.Z. Berlin, A.V. Meshcheryakov. Anesthesia and dosing of anesthetics. - M. : Medicine, 1980, p. 19).

This method has an advantage over the analogue in that the carrier gas is supplied under the anesthetic layer and mixes intensively during the evaporation process, which allows controlling the anesthetic temperature and, as a result, the vapor concentration in the evaporation chamber.

However, the disadvantage of this method is the inability to obtain a stable volume concentration of anesthetic vapor, due to the fact that, firstly, rotameters have a certain measurement error and, secondly, as the level of anesthetic decreases, the resistance of the evaporation chamber decreases, which leads to redistribution of flows and as a consequence, a change in vapor concentration at the outlet of the evaporator. It involves reconfiguration for each type of anesthetic.

A device for dispensing anesthetics is known, containing a microprocessor with an LCD display and a keyboard, a stepper motor, a syringe dispenser and two high pressure lines for supplying nitrous oxide and carrier gas, each of which consists of a control valve, linear pneumatic resistance and a differential pressure sensor moreover, the line for supplying nitrous oxide additionally contains a solenoid valve, and the line for supplying oxygen contains a pressure sensor, the input of nitrous oxide through the electromagnetic valve and through the first the first control valve is connected to the first linear pneumatic resistance, in parallel to which the first differential pressure sensor is installed, the oxygen supply inlet through the second control valve is connected to the second linear pneumatic resistance, in which the second differential pressure sensor is installed, in addition, the oxygen supply input is connected to the pressure sensor and the input of the emergency oxygen supply button, the output of which is connected to the outputs of the first and second linear pneumatic resistances nen with the input of the dispensing syringe, the output of which is the output of the device, the microprocessor with an LCD display and a keyboard, the first control output is connected to the control winding of the stepper motor, the output of which is connected to the rod of the syringe dispenser, the second control output to the emergency oxygen supply button, and the third control output - with a solenoid valve (RU No. 2197999, MKI A61M 16/01, publ. 02/10/03. Bull. No. 4.).

The disadvantage of this device is the design complexity and insufficiently accurate dosing of the volumetric concentration of vapor of liquid anesthetics.

It is also known a device for dispensing anesthetics, taken as a prototype, containing a line of a common stream of carrier gas, a first line with a valve and a second line of a shared common stream of carrier gas, an evaporator of a carrier gas stream line saturated with anesthetic vapor with a valve, a unit for mixing and mixing two separated streams and a supply line for a combined carrier gas stream to a consumer (See A.Z. Berlin, A.V. Meshcheryakov. Anesthesia and dosing of anesthetics. - M .: Medicine, 1980, p.19, Fig. 5).

Although this device has a less complex design, its drawback is the impossibility of obtaining a stable volume concentration of anesthetic vapor, which is associated with the fact that, firstly, rotameters have a certain measurement error and, secondly, as the evaporation chamber decreases, the resistance of the evaporation chamber drops, which leads to a redistribution of flows and, as a consequence, a change in the concentration of vapor at the outlet of the evaporator. It involves reconfiguration for each type of anesthetic.

The task of the group of inventions is to ensure that the required parameters for the accuracy of dosing of the volume concentration of vapor of liquid anesthetics are provided with the ability to use any kind of anesthetics while simplifying the design and increasing the reliability of the dosing devices.

The technical result to which the group of inventions is directed is to obtain a mobile and economically affordable method by reducing the cost of the device that implements it, and providing quick readjustment of changes in the concentration parameters of any anesthetic, as well as in ensuring a constant volume concentration regardless of the parameters of the incoming gas.

This is achieved by the fact that in the dosing method of the anesthetic, which includes the separation of the incoming total flow of carrier gas into two streams and their direction along two lines, the first of which is mixed with the second divided stream, going along the second line and passing through the evaporator with its supply under the anesthetic layer, its saturation with anesthetic pairs and their combination and mixing in the mixing chamber before being supplied to the consumer, the flows are separated, and the given concentration is achieved due to the cyclic overlapping of the second with simultaneous passage of the separated carrier gas stream along the first line with a continuously selected time interval, and then the first line is blocked with simultaneous passage of the separated carrier gas stream along the second line with a continuously selected other time interval, and then the separation cycle is repeated repeatedly, at this change in concentration is carried out by changing the ratio of the intervals of the opening and / or closing of the first and second lines.

This is achieved by the fact that the anesthetic dosing device comprising a line of a common carrier gas stream with a valve, a first line of a shared common carrier gas stream and a second line of a shared common carrier gas stream with an evaporator and a carrier gas stream line saturated with anesthetic vapor combining and mixing two separated streams and a supply line of a combined carrier gas stream of a given concentration to a consumer, has a valve with a timer for generating predetermined time intervals on the carrier gas line separating the incoming total defined volume of the carrier gas into two streams alternately cyclically at different time intervals, while with one line open, the other line of the divided total carrier gas stream is closed.

Description of the claimed invention is illustrated by drawings and diagrams:

figure 1 - shows a structural diagram of a device;

figure 2 - shows a gas flow diagram for creating a volumetric vapor concentration of 1%;

figure 3 - shows a gas flow diagram for creating a volume concentration of 2%;

figure 4 - conventionally shows the resulting mixture of carrier gas and anesthetic vapor with a given volume concentration at the outlet of the dispenser.

For the convenience of reviewing application materials, we first describe a device that implements anesthetic dosing method, which consists of a line of common carrier gas stream 1 with valve 2, valve 3 with a timer for separating the total carrier gas stream and supplying it alternately along two lines (in Fig. shown), the first line 4, the separated stream of carrier gas and the second line 5 of the divided stream of carrier gas, an evaporator 6 with a heater 7 and a temperature sensor 8, line 9 of the second divided stream of carrier gas saturated with anesthetic vapor, measures of association and mixing the two partial flows 10, supply line 11 the combined flow of carrier gas at the desired volume concentration of anesthetic vapor to a particular patient.

A device for dispensing anesthetics works as follows. By opening valve 2, the total carrier gas stream rushes toward valve 3. Valve 3 divides the total carrier gas stream into two streams, directing them alternately along two lines. This happens as follows. The total carrier gas stream first enters the inlet to valve 3, at which time the second line 5 is closed by valve 3, and the first line 4 is open to them. Therefore, part of the total carrier gas flow is directed to the first line 4. Then, valve 3 closes the first line 4 and opens the second line 5. Thus, the second part of the total carrier gas flow passing through valve 3 is directed to the second line 5. The first separation cycle the total carrier gas stream and its supply alternately along two lines is completed. Then the first line 4 and another opens again, but exactly the same as in the first separation cycle, part of the total carrier gas stream is sent to the first line 4. At this time, the second line 5 is closed. Then, valve 3 closes the first line 4 and opens the second line 5. Thereby, the other, exactly the same as in the first separation cycle, the second part of the total carrier gas stream, is sent to the second line 5, etc. The number of separation cycles depends on the consumer. Thus, the total flow of carrier gas is divided into two volumes - V ₁ and V ₂ proportional to the time intervals for opening T ₁ and T ₂ of the valve 3, directing them alternately first along the first line 4, and then along the second line 5, respectively. Where: - V _{1 is the} volume of carrier gas passing through the first line 4; V _{2 is the} volume of carrier gas passing through the second line 5; T ₁ - the time interval for opening the valve to pass V ₁ through the first line 4; T ₂ is the time interval for opening the valve for passing V ₂ through the second line 6. The time intervals for opening T ₁ and T ₂ are constant for each type of anesthetic and concentration depends on the ratio of these time intervals. The smaller the time intervals T ₁ opening line 4, the greater the concentration. Conversely, the larger the time intervals T ₁ opening line 4, the lower the concentration. The flow of the separated carrier gas entering the second line 5 is then supplied from below to the evaporator 6. In the evaporator 6, in which the liquid anesthetic is located, a constant temperature is maintained, which is monitored by a temperature sensor 8, for example a thermometer, and which is electrically connected to the heater 7. In this case, the carrier gas bubbles mix the anesthetic due to bubbling and, thus, the temperature throughout the volume of the liquid anesthetic is stabilized in the evaporator, including its upper layer, and the gas bubbles rer, in turn, to the saturated vapor of the anesthetic concentration determined thermophysical properties of steam. A saturated vapor-gas mixture is created in the evaporator, which, through line 9 of the saturated separated carrier gas stream, enters the mixing chamber 10 and, meeting with the incoming separated carrier gas stream passing through line 4, is mixed with it. Next, the combined stream with the desired volumetric vapor concentration is supplied through the supply line 11 of the carrier gas for a particular patient. In the patient’s expiration cycle, the mixed stream entering the carrier gas supply line 11 accumulates in the backup bag 12, and in the inspiration cycle this mixed stream, together with the part of the mixed stream that leaves the device during the inspiration cycle, enters the artificial lung ventilation apparatus (Mechanical ventilation) and to the patient.

A method for dispensing anesthetics involves dividing the total carrier gas stream passing through the general stream 1 line into two streams, the first of which goes along the first line 4 to mix with the second stream going through the second line 5 and passing through the evaporator 6 with its supply layer of anesthetic, its saturation with pairs of anesthetic and their subsequent combination and mixing in the mixing chamber 10. In this case, the separation of flows and a given concentration is carried out by cyclically overlapping the second line 5 with simultaneous skipping of the divided stream of carrier gas along the first line 4 with a continuously selected time interval, and then the first line 4 is shut off while simultaneously passing a divided stream of carrier gas along the second line 5 with a continuously selected other time interval. Then, the separation cycle of the common stream 1 is repeated. A change in concentration is carried out by changing the ratio of the intervals of the opening or closing time of the first and second lines.

A specific implementation of this method and device is as follows.

A constant flow of carrier gas O ₂ along the line of the total flow 1 of carrier gas with a diameter of, for example, 2 cm, with valve 2 open (see FIG. 1), rushes to the solenoid valve 3. For example, a three-way valve AZ21-1E2 of the Camozzi company with a timer for the formation, division and distribution of the total gas flow. Valve 3 divides the total flow generated by valve 2 into two volumes, V ₁ and V ₂ , proportional to the opening times, for example, T ₁ = 6.9 sec and T ₂ = 0.15 sec, of the first line 4 of the separated carrier gas stream, with a diameter of, for example, 2 cm, and a second line 5 of a separated flow of carrier gas, with a diameter of, for example, 2 cm, respectively. The carrier gas stream of a certain volume V ₁ arriving through valve 3 for a time T ₁ = 6.9 sec is directed to the first line 4 of the divided carrier gas stream and enters the combining and mixing chamber 10. At this time, the second gas line 5 of the divided gas carrier is closed. Then, valve 3 closes the first line 4 of the separated flow of carrier gas and opens the second line 5 of the divided flow for a time interval T ₂ = 0.15 sec. During this time, a certain volume V _{2 of the} separated carrier gas stream is sent to the second line 5 and enters the bottom of the evaporator 6 with a volume of 40 cm ³ . The vaporizer contains a liquid anesthetic, in our example, fluorotane, the temperature of which is constantly maintained at 20 ° C. In this case, the passage of the second separated carrier gas stream through the anesthetic is accompanied by the saturation of the carrier gas bubbles, which mix the liquid due to bubbling, and thereby the temperature throughout the volume of the liquid anesthetic is stabilized in the evaporator, including its upper layer. In the evaporator 6, a saturated vapor-gas mixture is created, which, through line 9 of the second separated carrier gas stream saturated with anesthetic vapor, also enters the combining and mixing chamber 10 for combining with the first divided volume of carrier gas, and the combined gas stream a carrier with the required concentration of anesthetic vapor is ready for delivery to the consumer. It turns out the first combined volume V _c = V ₁ + V ₂ with the desired volumetric concentration of the carrier gas for one cycle of the valve 3. Thus, the cycle time of the valve 3 is the time interval T _c = T ₁ + T ₂ . In our case, for a given volumetric concentration of fluorotan of 1%, volumetric T _c = 7.05 sec. This first combined volume of carrier gas with the required volume concentration of the vapor of the anesthetic flows through line 11 with a diameter of 2 cm, to a specific patient. Then the cycle repeats. Thus, a combined carrier gas stream is formed saturated with a certain concentration V _c × n during the time T _c × n (see Fig. 4).

Naturally, the volume concentration of anesthetic vapor in the mixture and the type of anesthetic depend on the time interval T ₁ = 6.91 during which the carrier gas from the valve outlet is sent to the first line 4. For fluorotan, for example, these intervals (at a liquid anesthetic temperature of 20 ° C) at T ₂ equal to, for example, 0.15 sec, the volume concentration is 1% (see figure 2).

When the time interval T ₁ = 3,43 sec volumetric concentration is 2% (see figure 3).

When the time interval T ₁ = 2,32 sec volumetric concentration is 3%.

At a time interval T ₁ = 1.725 sec, the volume concentration is 4%.

For other anesthetics, while maintaining the time interval T ₁ = 6.91 sec, T ₁ = 3.43 sec, T ₁ = 2.32 sec and T ₁ = 1.725 sec at T ₂ = 0.15 sec, the volume concentration will be other percentages , but strictly fixed for each time interval.

Thus, the group of inventions will provide the required accuracy parameters for dosing volumetric concentration of vapor of liquid anesthetics with the ability to use any kind of anesthetics while simplifying the design and improving the reliability of the metering devices.

Claims (2)

1. An anesthetic dosing method, comprising dividing the incoming total carrier gas stream into two streams and directing them along two lines, in the second line, the carrier gas stream is supplied to the evaporator under the anesthetic layer, saturated with anesthetic vapor, the temperature of which is maintained at 20 ° C, and before supplying the consumer, the flows are combined, characterized in that the separation of the carrier gas flows is carried out by cyclically shutting off the second line with the simultaneous passage of the separated carrier gas stream along the first line, thereby overlapping the first line while passing the separated carrier gas stream along the second line, along which the carrier gas stream passes through the evaporator, the separation cycle is repeated repeatedly, and the anesthetic concentration is changed by changing the ratio between the opening and closing time interval of the first line and the opening interval second line. 2. An anesthetic dosing device comprising a line of a common carrier gas stream with a valve, a first line of a divided common carrier gas stream, and a second line of a shared common carrier gas stream with an evaporator, a chamber for combining and mixing two separated streams, and a combined gas stream supply line a carrier with an anesthetic of a given concentration to a consumer, characterized in that a valve with a timer for forming the intervals of the incoming total bemsya carrier gas into two flow alternately cyclically, wherein the evaporator is provided with a heater and a temperature sensor, and on the carrier gas supply line with anesthetic installed backup storage bag carrier gas with anesthetic in the exhalation cycle.